For complex robots such as humanoids, model-based control is highly beneficial for accurate tracking while keeping negative feedback gains low for compliance. However, in such multi degree-of-freedom lightweight systems, conventional identification of rigid body dynamics models using CAD data and actuator models is inaccurate due to unknown nonlinear robot dynamic effects. An alternative method is data-driven parameter estimation, but significant noise in measured and inferred variables affects it adversely. Moreover, standard estimation procedures may give physically inconsistent results due to unmodeled nonlinearities or insufficiently rich data. This paper addresses these problems, proposing a Bayesian system identification technique for linear or piecewise linear systems. Inspired by Factor Analysis regression, we develop a computationally efficient variational Bayesian regression algorithm that is robust to ill-conditioned data, automatically detects relevant features, and identifies input and output noise. We evaluate our approach on rigid body parameter estimation for various robotic systems, achieving an error of up to three times lower than other state-of-the-art machine learning methods

One of the hallmarks of the performance, versatility, and robustness
of biological motor control is the ability to adapt the impedance of
the overall biomechanical system to different task requirements and
stochastic disturbances. A transfer of this principle to robotics is
desirable, for instance to enable robots to work robustly and safely
in everyday human environments. It is, however, not trivial to derive
variable impedance controllers for practical high degree-of-freedom
(DOF) robotic tasks.
In this contribution, we accomplish such variable impedance control
with the reinforcement learning (RL) algorithm PISq ({f P}olicy
{f I}mprovement with {f P}ath {f I}ntegrals). PISq is a
model-free, sampling based learning method derived from first
principles of stochastic optimal control. The PISq algorithm requires no tuning
of algorithmic parameters besides the exploration noise. The designer
can thus fully focus on cost function design to specify the task. From
the viewpoint of robotics, a particular useful property of PISq is
that it can scale to problems of many DOFs, so that reinforcement learning on real robotic
systems becomes feasible.
We sketch the PISq algorithm and its theoretical properties, and how
it is applied to gain scheduling for variable impedance control.
We evaluate our approach by presenting results on several simulated and real robots.
We consider tasks involving accurate tracking through via-points, and manipulation tasks requiring physical contact with the environment.
In these tasks, the optimal strategy requires both tuning of a reference trajectory emph{and} the impedance of the end-effector.
The results show that we can use path integral based reinforcement learning not only for
planning but also to derive variable gain feedback controllers in
realistic scenarios. Thus, the power of variable impedance control
is made available to a wide variety of robotic systems and practical
applications.

2009

Computational models of the neuromuscular system hold the potential to allow us to reach a deeper understanding of neuromuscular function and clinical rehabilitation by complementing experimentation. By serving as a means to distill and explore specific hypotheses, computational models emerge from prior experimental data and motivate future experimental work. Here we review computational tools used to understand neuromuscular function including musculoskeletal modeling, machine learning, control theory, and statistical model analysis. We conclude that these tools, when used in combination, have the potential to further our understanding of neuromuscular function by serving as a rigorous means to test scientific hypotheses in ways that complement and leverage experimental data.

Abstract The paper presents a two-layered system for (1) learning and encoding a periodic signal without any knowledge on its frequency and waveform, and (2) modulating the learned periodic trajectory in response to external events. The system is used to learn periodic tasks on a humanoid HOAP-2 robot. The first layer of the system is a dynamical system responsible for extracting the fundamental frequency of the input signal, based on adaptive frequency oscillators. The second layer is a dynamical system responsible for learning of the waveform based on a built-in learning algorithm. By combining the two dynamical systems into one system we can rapidly teach new trajectories to robots without any knowledge of the frequency of the demonstration signal. The system extracts and learns only one period of the demonstration signal. Furthermore, the trajectories are robust to perturbations and can be modulated to cope with a dynamic environment. The system is computationally inexpensive, works on-line for any periodic signal, requires no additional signal processing to determine the frequency of the input signal and can be applied in parallel to multiple dimensions. Additionally, it can adapt to changes in frequency and shape, e.g. to non-stationary signals, such as hand-generated signals and human demonstrations.

Locally-weighted regression is a computationally-efficient technique for non-linear regression.
However, for high-dimensional data, this technique becomes numerically brittle and computationally
too expensive if many local models need to be maintained simultaneously. Thus, local linear
dimensionality reduction combined with locally-weighted regression seems to be a promising solution.
In this context, we review linear dimensionality-reduction methods, compare their performance on nonparametric
locally-linear regression, and discuss their ability to extend to incremental learning. The
considered methods belong to the following three groups: (1) reducing dimensionality only on the input
data, (2) modeling the joint input-output data distribution, and (3) optimizing the correlation between
projection directions and output data. Group 1 contains principal component regression (PCR); group
2 contains principal component analysis (PCA) in joint input and output space, factor analysis, and
probabilistic PCA; and group 3 contains reduced rank regression (RRR) and partial least squares
(PLS) regression. Among the tested methods, only group 3 managed to achieve robust performance
even for a non-optimal number of components (factors or projection directions). In contrast, group 1
and 2 failed for fewer components since these methods rely on the correct estimate of the true intrinsic
dimensionality. In group 3, PLS is the only method for which a computationally-efficient incremental
implementation exists. Thus, PLS appears to be ideally suited as a building block for a locally-weighted
regressor in which projection directions are incrementally added on the fly.

Recent experimental and theoretical work [1] investigated the neural control of contact transition between motion and force during tapping with the index finger as a nonlinear optimization problem. Such transitions from motion to well-directed contact force are a fundamental part of dexterous manipulation. There are 3 alternative hypotheses of how this transition could be accomplished by the nervous system as a function of changes in direction and magnitude of the torque vector controlling the finger. These hypotheses are 1) an initial change in direction with a subsequent change in magnitude of the torque vector; 2) an initial change in magnitude with a subsequent directional change of the torque vector; and 3) a simultaneous and proportionally equal change of both direction and magnitude of the torque vector. Experimental work in [2] shows that the nervous system selects the first strategy, and in [1] we suggest that this may in fact be the optimal strategy. In [4] the framework of Iterative Linear Quadratic Optimal Regulator (ILQR) was extended to incorporate motion and force control. However, our prior simulation work assumed direct and instantaneous control of joint torques, which ignores the known delays and filtering properties of skeletal muscle.
In this study, we implement an ILQR controller for a more biologically plausible biomechanical model of the index finger than [4], and add activation-contraction dynamics to the system to simulate muscle function. The planar biomechanical model includes the kinematics of the 3 joints while the applied torques are driven by activation?contraction dynamics with biologically plausible time constants [3]. In agreement with our experimental work [2], the task is to, within 500 ms, move the finger from a given resting configuration to target configuration with a desired terminal velocity. ILQR does not only stabilize the finger dynamics according to the objective function, but it also generates smooth joint space trajectories with minimal tuning and without an a-priori initial control policy (which is difficult to find for highly dimensional biomechanical systems).
Furthemore, the use of this optimal control framework and the addition of activation-contraction dynamics considers the full nonlinear dynamics of the index finger and produces a sequence of postures which are compatible with experimental motion data [2]. These simulations combined with prior experimental results suggest that optimal control is a strong candidate for the generation of finger movements prior to abrupt motion-to-force transitions.
This work is funded in part by grants NIH R01 0505520 and NSF EFRI-0836042 to Dr. Francisco J. Valero- Cuevas
1 Venkadesan M, Valero-Cuevas FJ. Effects of neuromuscular lags on controlling contact transitions. Philosophical Transactions of the Royal Society A: 2008.
2 Venkadesan M, Valero-Cuevas FJ. Neural Control of Motion-to-Force Transitions with the Fingertip. J. Neurosci., Feb 2008; 28: 1366 - 1373;
3 Zajac. Muscle and tendon: properties, models, scaling, and application to biomechanics and motor control. Crit Rev Biomed Eng, 17
4. Weiwei Li., Francisco Valero Cuevas: ?Linear Quadratic Optimal Control of Contact Transition with Fingertip ? ACC 2009

Abstract The paper presents a two-layered system for (1) learning and encoding a periodic signal without any knowledge on its frequency and waveform, and (2) modulating the learned periodic trajectory in response to external events. The system is used to learn periodic tasks on a humanoid HOAP-2 robot. The first layer of the system is a dynamical system responsible for extracting the fundamental frequency of the input signal, based on adaptive frequency oscillators. The second layer is a dynamical system responsible for learning of the waveform based on a built-in learning algorithm. By combining the two dynamical systems into one system we can rapidly teach new trajectories to robots without any knowledge of the frequency of the demonstration signal. The system extracts and learns only one period of the demonstration signal. Furthermore, the trajectories are robust to perturbations and can be modulated to cope with a dynamic environment. The system is computationally inexpensive, works on-line for any periodic signal, requires no additional signal processing to determine the frequency of the input signal and can be applied in parallel to multiple dimensions. Additionally, it can adapt to changes in frequency and shape, e.g. to non-stationary signals, such as hand-generated signals and human demonstrations.

2008

One of the most general frameworks for phrasing control problems for
complex, redundant robots is operational space control. However, while
this framework is of essential importance for robotics and well-understood
from an analytical point of view, it can be prohibitively hard to achieve
accurate control in face of modeling errors, which are inevitable in com-
plex robots, e.g., humanoid robots. In this paper, we suggest a learning
approach for opertional space control as a direct inverse model learning
problem. A ï¬rst important insight for this paper is that a physically cor-
rect solution to the inverse problem with redundant degrees-of-freedom
does exist when learning of the inverse map is performed in a suitable
piecewise linear way. The second crucial component for our work is based
on the insight that many operational space controllers can be understood
in terms of a constrained optimal control problem. The cost function as-
sociated with this optimal control problem allows us to formulate a learn-
ing algorithm that automatically synthesizes a globally consistent desired
resolution of redundancy while learning the operational space controller.
From the machine learning point of view, this learning problem corre-
sponds to a reinforcement learning problem that maximizes an immediate
reward. We employ an expectation-maximization policy search algorithm
in order to solve this problem. Evaluations on a three degrees of freedom
robot arm are used to illustrate the suggested approach. The applica-
tion to a physically realistic simulator of the anthropomorphic SARCOS
Master arm demonstrates feasibility for complex high degree-of-freedom
robots. We also show that the proposed method works in the setting of
learning resolved motion rate control on real, physical Mitsubishi PA-10
medical robotics arm.

Dexterous manipulation with a highly redundant movement system is one of the hallmarks of hu-
man motor skills. From numerous behavioral studies, there is strong evidence that humans employ
compliant task space control, i.e., they focus control only on task variables while keeping redundant
degrees-of-freedom as compliant as possible. This strategy is robust towards unknown disturbances
and simultaneously safe for the operator and the environment. The theory of operational space con-
trol in robotics aims to achieve similar performance properties. However, despite various compelling
theoretical lines of research, advanced operational space control is hardly found in actual robotics imple-
mentations, in particular new kinds of robots like humanoids and service robots, which would strongly
profit from compliant dexterous manipulation. To analyze the pros and cons of different approaches
to operational space control, this paper focuses on a theoretical and empirical evaluation of different
methods that have been suggested in the literature, but also some new variants of operational space
controllers. We address formulations at the velocity, acceleration and force levels. First, we formulate
all controllers in a common notational framework, including quaternion-based orientation control, and
discuss some of their theoretical properties. Second, we present experimental comparisons of these
approaches on a seven-degree-of-freedom anthropomorphic robot arm with several benchmark tasks.
As an aside, we also introduce a novel parameter estimation algorithm for rigid body dynamics, which
ensures physical consistency, as this issue was crucial for our successful robot implementations. Our
extensive empirical results demonstrate that one of the simplified acceleration-based approaches can
be advantageous in terms of task performance, ease of parameter tuning, and general robustness and
compliance in face of inevitable modeling errors.

In this paper we introduce an improved implementation of locally weighted projection regression
(LWPR), a supervised learning algorithm that is capable of handling high-dimensional input data.
As the key features, our code supports multi-threading, is available for multiple platforms, and
provides wrappers for several programming languages.

2007

HFSP Journal Frontiers of Interdisciplinary Research in the Life Sciences, 1(2):115-126, 2007, clmc (article)

Abstract

Research in robotics has moved away from its primary focus on industrial
applications. The New Robotics is a vision that has been developed in past years
by our own university and many other national and international research
instiutions and addresses how increasingly more human-like robots can live
among us and take over tasks where our current society has shortcomings. Elder
care, physical therapy, child education, search and rescue, and general
assistance in daily life situations are some of the examples that will benefit from
the New Robotics in the near future. With these goals in mind, research for the
New Robotics has to embrace a broad interdisciplinary approach, ranging from
traditional mathematical issues of robotics to novel issues in psychology,
neuroscience, and ethics. This paper outlines some of the important research
problems that will need to be resolved to make the New Robotics a reality.

2002

In recent years, an increasing number of research projects investigated whether the central nervous system employs internal models in motor control. While inverse models in the control loop can be identified more readily in both motor behavior and the firing of single neurons, providing direct evidence for the existence of forward models is more complicated. In this paper, we will discuss such an identification of forward models in the context of the visuomotor control of an unstable dynamic system, the balancing of a pole on a finger. Pole balancing imposes stringent constraints on the biological controller, as it needs to cope with the large delays of visual information processing while keeping the pole at an unstable equilibrium. We hypothesize various model-based and non-model-based control schemes of how visuomotor control can be accomplished in this task, including Smith Predictors, predictors with Kalman filters, tapped-delay line control, and delay-uncompensated control. Behavioral experiments with human participants allow exclusion of most of the hypothesized control schemes. In the end, our data support the existence of a forward model in the sensory preprocessing loop of control. As an important part of our research, we will provide a discussion of when and how forward models can be identified and also the possible pitfalls in the search for forward models in control.

Locally weighted learning (LWL) is a class of techniques from nonparametric statistics that provides useful representations and training algorithms for learning about complex phenomena during autonomous adaptive control of robotic systems. This paper introduces several LWL algorithms that have been tested successfully in real-time learning of complex robot tasks. We discuss two major classes of LWL, memory-based LWL and purely incremental LWL that does not need to remember any data explicitly. In contrast to the traditional belief that LWL methods cannot work well in high-dimensional spaces, we provide new algorithms that have been tested on up to 90 dimensional learning problems. The applicability of our LWL algorithms is demonstrated in various robot learning examples, including the learning of devil-sticking, pole-balancing by a humanoid robot arm, and inverse-dynamics learning for a seven and a 30 degree-of-freedom robot. In all these examples, the application of our statistical neural networks techniques allowed either faster or more accurate acquisition of motor control than classical control engineering.

A general theory of movement-pattern perception based on bi-directional theory for sensory-motor integration can be used for motion capture and learning by watching in robotics. We demonstrate our methods using the game of Kendama, executed by the SARCOS Dextrous Slave Arm, which has a very similar kinematic structure to the human arm. Three ingredients have to be integrated for the successful execution of this task. The ingredients are (1) to extract via-points from a human movement trajectory using a forward-inverse relaxation model, (2) to treat via-points as a control variable while reconstructing the desired trajectory from all the via-points, and (3) to modify the via-points for successful execution. In order to test the validity of the via-point representation, we utilized a numerical model of the SARCOS arm, and examined the behavior of the system under several conditions.

The skill of rhythmic juggling a ball on a racket is investigated from the viewpoint of nonlinear dynamics. The difference equations that model the dynamical system are analyzed by means of local and non-local stability analyses. These analyses yield that the task dynamics offer an economical juggling pattern which is stable even for open-loop actuator motion. For this pattern, two types of pre dictions are extracted: (i) Stable periodic bouncing is sufficiently characterized by a negative acceleration of the racket at the moment of impact with the ball; (ii) A nonlinear scaling relation maps different juggling trajectories onto one topologically equivalent dynamical system. The relevance of these results for the human control of action was evaluated in an experiment where subjects performed a comparable task of juggling a ball on a paddle. Task manipulations involved different juggling heights and gravity conditions of the ball. The predictions were confirmed: (i) For stable rhythmic performance the paddle's acceleration at impact is negative and fluctuations of the impact acceleration follow predictions from global stability analysis; (ii) For each subject, the realizations of juggling for the different experimental conditions are related by the scaling relation. These results allow the conclusion that for the given task, humans reliably exploit the stable solutions inherent to the dynamics of the task and do not overrule these dynamics by other control mechanisms. The dynamical scaling serves as an efficient principle to generate different movement realizations from only a few parameter changes and is discussed as a dynamical formalization of the principle of motor equivalence.

1993

Besides functional regards, product design demands increasingly more for further reaching considerations. Quality alone cannot suffice anymore to compete in the market; design for manufacturability, for assembly, for recycling, etc., are well-known keywords. Those can largely be reduced to the necessity of design for costs. This paper focuses on a CAD-based approach to design concurrent calculation. It will discuss how, in the meantime well-established, tools like feature technology, knowledge-based systems, and relational databases can be blended into one coherent concept to achieve an entirely CAD- and data-integrated cost information tool. This system is able to extract data from the CAD-system, combine it with data about the company specific manufacturing environment, and subsequently autonomously evaluate manufacturability aspects and costs of the given CAD-model. Within minutes the designer gets quantitative in-formation about the major cost sources of his/her design. Additionally, some alternative methods for approximating manu-facturing times from empirical data, namely neural networks and local weighted regression, are introduced.

1993

Our goal is to understand the principles of Perception, Action and Learning in autonomous systems that successfully interact with complex environments and to use this understanding to design future systems